Neutrino interferometry for high-precision tests of Lorentz symmetry with IceCube

The IceCube Collaboration

doi:10.1038/s41567-018-0172-2

Neutrino interferometry for high-precision tests of Lorentz symmetry with IceCube

The IceCube Collaboration

Chair of Experimental Physics with Cosmic Particles

University of Adelaide
Deutsches Elektronen-Synchrotron (DESY)
University of Canterbury
Université Libre de Bruxelles
Niels Bohr Institutet
Stockholm University
University of Geneva
Friedrich Alexander Universität Erlangen-Nürnberg
Marquette University
The Pennsylvania State University
Massachusetts Institute of Technology
RWTH Aachen University
South Dakota School of Mines and Technology
University of Alberta
University of Oxford
University of California, Irvine
Johannes Gutenberg University
University of California at Berkeley
Ohio State University
Max-Planck-lnstitut für Kohlenforschung
Bergische Universität Wuppertal
University of Rochester
University of Maryland
University of Kansas
Lawrence Berkeley National Laboratory
pro3dure medical GmbH
Sungkyunkwan University
Uppsala University
University of Wisconsin-Madison
VUB Neurology
SNOLAB
University of Münster
Technical University of Munich
Michigan State University
University of Delaware
Ghent University
Humboldt-Universität zu Berlin
Southern University and A&M College
University of Tokyo
Chiba-U
Clark-Atlanta University
University of Texas at Arlington
Queen Mary University of London
SUNY
Universitee de Mons
Physics Dept., University of Alabama
Drexel University
University of Wisconsin-River Falls
Yale University
University of Alaska Anchorage
Georgia Institute of Technology

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96 Scopus citations

Abstract

Lorentz symmetry is a fundamental spacetime symmetry underlying both the standard model of particle physics and general relativity. This symmetry guarantees that physical phenomena are observed to be the same by all inertial observers. However, unified theories, such as string theory, allow for violation of this symmetry by inducing new spacetime structure at the quantum gravity scale. Thus, the discovery of Lorentz symmetry violation could be the first hint of these theories in nature. Here we report the results of the most precise test of spacetime symmetry in the neutrino sector to date. We use high-energy atmospheric neutrinos observed at the IceCube Neutrino Observatory to search for anomalous neutrino oscillations as signals of Lorentz violation. We find no evidence for such phenomena. This allows us to constrain the size of the dimension-four operator in the standard-model extension for Lorentz violation to the 1 0 ^{- 28} level and to set limits on higher-dimensional operators in this framework. These are among the most stringent limits on Lorentz violation set by any physical experiment.

Original language	English
Pages (from-to)	961-966
Number of pages	6
Journal	Nature Physics
Volume	14
Issue number	9
DOIs	https://doi.org/10.1038/s41567-018-0172-2
State	Published - 1 Sep 2018

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10.1038/s41567-018-0172-2

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title = "Neutrino interferometry for high-precision tests of Lorentz symmetry with IceCube",

abstract = "Lorentz symmetry is a fundamental spacetime symmetry underlying both the standard model of particle physics and general relativity. This symmetry guarantees that physical phenomena are observed to be the same by all inertial observers. However, unified theories, such as string theory, allow for violation of this symmetry by inducing new spacetime structure at the quantum gravity scale. Thus, the discovery of Lorentz symmetry violation could be the first hint of these theories in nature. Here we report the results of the most precise test of spacetime symmetry in the neutrino sector to date. We use high-energy atmospheric neutrinos observed at the IceCube Neutrino Observatory to search for anomalous neutrino oscillations as signals of Lorentz violation. We find no evidence for such phenomena. This allows us to constrain the size of the dimension-four operator in the standard-model extension for Lorentz violation to the 1 0 - 28 level and to set limits on higher-dimensional operators in this framework. These are among the most stringent limits on Lorentz violation set by any physical experiment.",

author = "\{The IceCube Collaboration\} and Aartsen, \{M. G.\} and Hill, \{G. C.\} and A. Kyriacou and S. Robertson and A. Wallace and Whelan, \{B. J.\} and M. Ackermann and E. Bernardini and S. Blot and F. Bradascio and Bretz, \{H. P.\} and J. Brostean-Kaiser and A. Franckowiak and E. Jacobi and T. Karg and T. Kintscher and S. Kunwar and R. Nahnhauer and K. Satalecka and C. Spiering and J. Stachurska and A. Stasik and Strotjohann, \{N. L.\} and A. Terliuk and M. Usner and \{van Santen\}, J. and J. Adams and H. Bagherpour and Aguilar, \{J. A.\} and I. Ansseau and D. Heereman and K. Meagher and T. Meures and A. O{\textquoteright}Murchadha and E. Pinat and C. Raab and M. Ahlers and E. Bourbeau and Koskinen, \{D. J.\} and Larson, \{M. J.\} and M. Medici and M. Rameez and T. Stuttard and M. Ahrens and C. Bohm and Dumm, \{J. P.\} and C. Finley and S. Flis and K. Hultqvist and E. Resconi",

note = "Publisher Copyright: {\textcopyright} 2018, The Author(s).",

year = "2018",

month = sep,

day = "1",

doi = "10.1038/s41567-018-0172-2",

language = "English",

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AU - The IceCube Collaboration

AU - Aartsen, M. G.

AU - Hill, G. C.

AU - Kyriacou, A.

AU - Robertson, S.

AU - Wallace, A.

AU - Whelan, B. J.

AU - Ackermann, M.

AU - Bernardini, E.

AU - Blot, S.

AU - Bradascio, F.

AU - Bretz, H. P.

AU - Brostean-Kaiser, J.

AU - Franckowiak, A.

AU - Jacobi, E.

AU - Karg, T.

AU - Kintscher, T.

AU - Kunwar, S.

AU - Nahnhauer, R.

AU - Satalecka, K.

AU - Spiering, C.

AU - Stachurska, J.

AU - Stasik, A.

AU - Strotjohann, N. L.

AU - Terliuk, A.

AU - Usner, M.

AU - van Santen, J.

AU - Adams, J.

AU - Bagherpour, H.

AU - Aguilar, J. A.

AU - Ansseau, I.

AU - Heereman, D.

AU - Meagher, K.

AU - Meures, T.

AU - O’Murchadha, A.

AU - Pinat, E.

AU - Raab, C.

AU - Ahlers, M.

AU - Bourbeau, E.

AU - Koskinen, D. J.

AU - Larson, M. J.

AU - Medici, M.

AU - Rameez, M.

AU - Stuttard, T.

AU - Ahrens, M.

AU - Bohm, C.

AU - Dumm, J. P.

AU - Finley, C.

AU - Flis, S.

AU - Hultqvist, K.

AU - Resconi, E.

PY - 2018/9/1

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N2 - Lorentz symmetry is a fundamental spacetime symmetry underlying both the standard model of particle physics and general relativity. This symmetry guarantees that physical phenomena are observed to be the same by all inertial observers. However, unified theories, such as string theory, allow for violation of this symmetry by inducing new spacetime structure at the quantum gravity scale. Thus, the discovery of Lorentz symmetry violation could be the first hint of these theories in nature. Here we report the results of the most precise test of spacetime symmetry in the neutrino sector to date. We use high-energy atmospheric neutrinos observed at the IceCube Neutrino Observatory to search for anomalous neutrino oscillations as signals of Lorentz violation. We find no evidence for such phenomena. This allows us to constrain the size of the dimension-four operator in the standard-model extension for Lorentz violation to the 1 0 - 28 level and to set limits on higher-dimensional operators in this framework. These are among the most stringent limits on Lorentz violation set by any physical experiment.

AB - Lorentz symmetry is a fundamental spacetime symmetry underlying both the standard model of particle physics and general relativity. This symmetry guarantees that physical phenomena are observed to be the same by all inertial observers. However, unified theories, such as string theory, allow for violation of this symmetry by inducing new spacetime structure at the quantum gravity scale. Thus, the discovery of Lorentz symmetry violation could be the first hint of these theories in nature. Here we report the results of the most precise test of spacetime symmetry in the neutrino sector to date. We use high-energy atmospheric neutrinos observed at the IceCube Neutrino Observatory to search for anomalous neutrino oscillations as signals of Lorentz violation. We find no evidence for such phenomena. This allows us to constrain the size of the dimension-four operator in the standard-model extension for Lorentz violation to the 1 0 - 28 level and to set limits on higher-dimensional operators in this framework. These are among the most stringent limits on Lorentz violation set by any physical experiment.

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U2 - 10.1038/s41567-018-0172-2

DO - 10.1038/s41567-018-0172-2

M3 - Article

AN - SCOPUS:85049992763

SN - 1745-2473

VL - 14

SP - 961

EP - 966

JO - Nature Physics

JF - Nature Physics

IS - 9

ER -

Neutrino interferometry for high-precision tests of Lorentz symmetry with IceCube

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